增材制造的极端温度电子封装

D. Shaddock, C. Hoel, N. Stoffel, M. Poliks, M. Alhendi
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引用次数: 1

摘要

人们对极端温度电子设备越来越感兴趣,以支持在商业和军事应用的正常操作范围之外的温度下进行感知、驱动和通信的任务需求。使用传统混合电路技术的陶瓷多芯片模块已经证明了在超过300°C的温度范围内的可靠封装。这种方法通常需要较高的NRE成本和交货期。金属、陶瓷、导体和电介质的增材制造工艺提供了混合电路制造技术的数字化转型,减少了封装的时间和成本,并具有新颖的3D结构和嵌入式功能。本报告介绍了测试结果,以表征增材制造的封装材料(基板,导体,电介质)的重要电气和机械性能,以及300至750°C电子封装设计所需的模具互连方法。
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Additively Manufactured Extreme Temperature Electronics Packaging
There is growing interest in extreme temperature electronics to support the mission needs to sense, actuate, and communicate at temperatures beyond the normal range of operations in commercial and military applications. Reliable packaging in the temperature range of more than 300°C has been demonstrated using ceramic multi-chip modules using conventional hybrid circuit technology. This approach typically requires high NRE costs and lead time. Additive manufacturing processes of metals, ceramics, conductors, and dielectrics provides a digital transformation of hybrid circuit manufacturing technology that reduces time and cost for packaging with the added benefits of novel 3D structures and embedded features. This report presents the results of testing to characterize important electrical and mechanical properties of additively manufactured packaging materials (substrates, conductor, dielectrics) and die interconnect methods needed for 300 to 750 °C electronic packaging designs.
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